' As accelerator science and technology progressed over the past several decades, the accelerators themselves have undergone major improvements in multiple performance factors: beam energy, beam power, and beam brightness. As a consequence, accelerators have found applications in a wide range of fields in our life and in our society. The current volume is dedicated to applications in energy and security, two of the most important and urgent topics in today''s world. This volume makes an effort to provide a review as complete and up to date as possible of this broad and challenging subject. It contains overviews on each of the two topics and a series of articles for in-depth discussions including heavy ion accelerator driven inertial fusion, linear accelerator-based ADS systems, circular accelerator-based ADS systems, accelerator-reactor interface, accelerators for fusion material testing, cargo inspection, proton radiography, compact neutron generators and detectors. It also has a review article on accelerator science and technology in Canada with a focus on the TRIUMF laboratory, and an article on the life of Bruno Touschek, a renowned accelerator physicist. Contents:Overview of Accelerator Applications in Energy (R W Garnett and R L Sheffield)Overview of Accelerator Applications for Security and Defense (A J Antolak)Heavy Ion Accelerator–Driven Inertial Fusion (I Hofmann)ADS Based on Linear Accelerators (W-M Pan and J-P Dai)Cyclotrons and FFAG Accelerators as Drivers for ADS (L Calabretta and F Méot)Accelerator–Reactor Coupling for Energy Production in Advanced Nuclear Fuel Cycles (F Heidet, N R Brown and M Haj Tahar)Accelerators for Fusion Materials Testing (J Knaster and Y Okumura)Low Energy Accelerators for Cargo Inspection (C-X Tang)Flash Proton Radiography (F E Merrill)Compact Neutron Sources for Energy and Security (M Uesaka and H Kobayashi)Detectors for Accelerator-Based Security Applications (G A Warren, S C Stave and E A Miller)Accelerator Science and Technology in Canada — From the Microtron to TRIUMF, Superconducting Cyclotrons and the Canadian Light Source (M K Craddock and R E Laxdal)Bruno Touschek: From Betatrons to Electron–Positron Colliders (C Bernardini, G Pancheri and C Pellegrini) Readership: Physicists and engineers in accelerator science and industry. Keywords:Accelerator Applications in Energy;Accelerator Applications in Security;Accelerator–Reactor Interface;ADS System;Fusion Material Testing;Proton Radiography;TRIUMF Lab;Bruno Touschek'

Since its invention in the 1920s, particle accelerators have made tremendous progress in accelerator science, technology and applications. However, the fundamental acceleration principle, namely, to apply an external radiofrequency (RF) electric field to accelerate charged particles, remains unchanged. As this method (either room temperature RF or superconducting RF) is approaching its intrinsic limitation in acceleration gradient (measured in MeV/m), it becomes apparent that new methods with much higher acceleration gradient (measured in GeV/m) must be found for future very high energy accelerators as well as future compact (table-top or room-size) accelerators. This volume introduces a number of advanced accelerator concepts (AAC) — their principles, technologies and potential applications. For the time being, none of them stands out as a definitive direction in which to go. But these novel ideas are in hot pursuit and look promising. Furthermore, some AAC requires a high power laser system. This has the implication of bringing two different communities — accelerator and laser — to join forces and work together. It will have profound impact on the future of our field. Also included are two special articles, one on "Particle Accelerators in China' which gives a comprehensive overview of the rapidly growing accelerator community in China. The other features the person-of-the-issue who was well-known nuclear physicist Jerome Lewis Duggan, a pioneer and founder of a huge community of industrial and medical accelerators in the US.

Understanding and controlling the physics of space charge effects in linear and circular proton and ion accelerators are essential to their operation, and to future high-intensity facilities. This book presents the status quo of this field from a theoretical perspective, compares analytical approaches with multi-particle computer simulations and – where available – with experiments. It discusses fundamental concepts of phase space motion, matched beams and modes of perturbation, along with mathematical models of analysis – from envelope to Vlasov-Poisson equations. The main emphasis is on providing a systematic description of incoherent and coherent resonance phenomena; parametric instabilities and sum modes; mismatch and halo; error driven resonances; and emittance exchange due to anisotropy, as well as the role of Landau damping. Their distinctive features are elaborated in the context of numerous sample simulations, and their potential impacts on beam quality degradation and beam loss are discussed. The book is intended for advanced beginners in accelerator research, and for experts interested in the mechanisms of direct space charge interaction and their modeling.

Since their debut in the late 1920s, particle accelerators have evolved into a backbone for the development of science and technology in modern society. Of about 30,000 accelerators at work in the world today, a majority is for applications in industry (about 20,000 systems worldwide). There are two major categories of industrial applications: materials processing and treatment, and materials analysis. Materials processing and treatment includes ion implantation (semi-conductor materials, metals, ceramics, etc.) and electron beam irradiation (sterilization of medical devices, food pasteurization, treatment of carcasses and tires, cross-linking of polymers, cutting and welding, curing of composites, etc.). Materials analysis covers ion beam analysis (IBA), non-destructive detection using photons and neutrons, as well as accelerator mass spectrometry (AMS). All the products that are processed, treated and inspected using beams from particle accelerators are estimated to have a collective value of US$500 billion per annum worldwide. Accelerators are also applied for environment protection, such as purifying drinking water, treating waste water, disinfecting sewage sludge and removing pollutants from flue gases. Industrial accelerators continue to evolve, in terms of new applications, qualities and capabilities, and reduction of their costs. Breakthroughs are encountered whenever a new product is made, or an existing product becomes more cost effective. Their impact on our society continues to grow with the potential to address key issues in economics or the society of today. This volume contains fourteen articles, all authored by renowned scientists in their respective fields. Contents:Trends for Electron Beam Accelerator Applications in Industry (Sueo Machi)Ion Implantation for Semiconductor Doping and Materials Modification (Lawrence A Larson, Justin M Williams and Michael I Current)Ion Beam Analysis: A Century of Exploiting the Electronic and Nuclear Structure of the Atom for Materials Characterisation (Chris Jeynes, Roger P Webb and Annika Lohstroh)Neutrons and Photons in Non-Destructive Detection (J F Harmon, D P Wells and A W Hunt)Review of Cyclotrons for the Production of Radioactive Isotopes for Medical and Industrial Applications (Paul Schmor)Development of Accelerator Mass Spectrometry and Its Applications (Jiaer Chen, Zhiyu Guo, Kexin Liu and Liping Zhou)Electron Accelerators for Environment Protection (Andrzej G Chmielewski)Studying Radiation Damage in Structural Materials by Using Ion Accelerators (Peter Hosemann)Direct Current Accelerators for Industrial Applications (Ragnar Hellborg and Harry J Whitlow)Radio-Frequency Electron Accelerators for Industrial Applications (Marshall R Cleland)Accelerators for Neutron Generation and Their Applications (Guenter Mank, Guenter Bauer and Françoise Mulhauser)Prospects for Accelerator Technology (Alan Todd)CERN: From Birth to Success (Herwig Schopper)Simon van der Meer (1925–2011): A Modest Genius of Accelerator Science (Vinod C Chohan) Readership: Physicists and engineers in accelerator science and industry. Keywords:Particle Accelerators;Materials Processing and Treatment;Materials Analysis;Industrial Accelerators;LHC;EnvironmentReviews: "The book is a very helpful way to be introduced in the world of accelerators as powerful tools to carry out quite a big number of applications that play a significant role in common life." IL Nuovo Saggiatore

Originally invented for generating the first artificial nuclear reactions, particle accelerators have undergone, during the past 80 years, a fascinating development that is an impressive example of the inventiveness and perseverance of scientists and engineers. Since the early 1980s, accelerator science and technology has been booming. Today, accelerators are the prime tool for high energy physics to probe the structure of matter to an unknown depth. They are also, as synchrotron radiation sources, the most versatile tool for characterizing materials and processes and for producing micro- and nanostructured devices. The determination of the structure of large biomolecules is presently among the best examples of the application of synchrotron radiation. Finally, accelerators have grown more and more important for medicine, which is relying on them for advanced cancer therapy and radio-surgery. And there are more applications, including the generation of neutrons for materials science, the transmutation of nuclear waste with simultaneous production of electrical power, the sterilization of medical supplies and of foodstuff, and the inspection of trucks by customs or security services. This book is meant to provide basic training in modern accelerators for students, teachers, and interested scientists and engineers working in other fields. It is a result of the 3rd International Accelerator School, held in 2002 in Singapore under the auspices of the Overseas Chinese Physics Association (OCPA). Reputable experts, including a recent prize-winner, cover the field of cyclic and linear accelerators from the basic theoretical tools to forefront developments such as the X-ray free electron laser or the latest proton therapy facilities under construction. Accelerators, the art of building them, and the science for understanding their function have become a very exciting field of research. This book conveys the excitement of the experts to the reader. The proceedings have been selected for coverage in: • Index to Scientific & Technical Proceedings® (ISTP® / ISI Proceedings) • Index to Scientific & Technical Proceedings (ISTP CDROM version / ISI Proceedings) • CC Proceedings — Engineering & Physical Sciences Contents:Particle Accelerators: An Introduction (C Zhang)A Guided Survey of Synchrotron Radiation Sources (H O Moser)Transverse Beam Dynamics: Linear Optics (Q Qin)Transverse Beam Dynamics: Closed Orbit Correction and Injection (C-C Kuo)Transverse Beam Dynamics: Dynamic Aperture (Q Qin)Longitudinal Beam Dynamics — Energy Oscillation in an Electron Storage Ring (Y Jin)Photoinjectors (I Ben-Zvi)Synchrotron Radiation (C T Lee)Lattice Design for Synchrotron Radiation Source Storage Rings (Y Jin)Spallation Neutron Source and Other High Intensity Proton Sources (W Chou)RF Electron Linac and Microton (S-H Wang)Collective Beam Effects in Storage Rings (Z Guo)Designing Superconducting Cavities for Accelerators (H Padamsee)Accelerator Magnets: Dipole, Quadrupole and Sextupole (C S Hwang)Emittance and Cooling (C T Lee)RF Systems for Light Source Storage Rings (Z T Zhao)Vacuum System (J R Chen)RFQ Design and Performance (J Fang)Insertion Devices: Wigglers and Undulators (C S Hwang)Medical and Industrial Applications of Electron Accelerators (Y Lin)High Gain Free Electron Lasers (L H Yu)Proton Therapy: Accelerator Aspects and Procedures (H-U Klein & D Krischel)Introduction to Synchrotron Radiation Applications (H O Moser et al.) Readership: Researchers, practitioners, academics and graduate students in accelerator physics. Keywords:Accelerator Physics;Particle Accelerators Synchrotron Radiation;Micro and Nanostructured Devices;Electron Laser X-Ray Free

This volume constitutes the state-of-the-art in active interrogation, widely recognized as indispensable methods for addressing current and future nuclear security needs. Written by a leading group of science and technology experts, this comprehensive reference presents technologies and systems in the context of the fundamental physics challenges and practical requirements. It compares the features, limitations, technologies, and impact of passive and active measurement techniques; describes radiation sources for active interrogation including electron and ion accelerators, intense lasers, and radioisotope-based sources; and it describes radiation detectors used for active interrogation. Entire chapters are devoted to data acquisition and processing systems, modeling and simulation, data interpretation and algorithms, and a survey of working active measurement systems. Active Interrogation in Nuclear Security is structured to appeal to a range of audiences, including graduate students, active researchers in the field, and policy analysts. The first book devoted entirely to active interrogation Presents a focused review of the relevant physics Surveys available technology Analyzes scientific and technology trends Provides historical and policy context Igor Jovanovic is a Professor of Nuclear Engineering and Radiological Sciences at the University of Michigan and has previously also taught at Penn State University and Purdue University. He received his Ph.D. from University of California, Berkeley and worked as physicist at Lawrence Livermore National Laboratory. Dr. Jovanovic has made numerous contributions to the science and technology of radiation detection, as well as the radiation sources for use in active interrogation in nuclear security. He has taught numerous undergraduate and graduate courses in areas that include radiation detection, nuclear physics, and nuclear security. At University of Michigan Dr. Jovanovic is the director of Neutron Science Laboratory and is also associated with the Center for Ultrafast Optical Science. Anna Erickson is an Assistant Professor in the Nuclear and Radiological Engineering Program of the G.W. Woodruff School of Mechanical Engineering at Georgia Institute of Technology. Previously, she was a postdoctoral researcher in the Advanced Detectors Group at Lawrence Livermore National Laboratory. Dr. Erickson received her PhD from Massachusetts Institute of Technology with a focus on radiation detection for active interrogation applications. Her research interests focus on nuclear non-proliferation including antineutrino analysis and non-traditional detector design and characterization. She teaches courses in advanced experimental detection for reactor and nuclear nonproliferation applications, radiation dosimetry and fast reactor analysis.

The Thorium Energy Conference (ThEC13) gathered some of the world’s leading experts on thorium technologies to review the possibility of destroying nuclear waste in the short term, and replacing the uranium fuel cycle in nuclear systems with the thorium fuel cycle in the long term. The latter would provide abundant, reliable and safe energy with no CO2 production, no air pollution, and minimal waste production. The participants, representatives of 30 countries, included Carlo Rubbia, Nobel Prize Laureate in physics and inventor of the Energy Amplifier; Jack Steinberger, Nobel Prize Laureate in physics; Hans Blix, former Director General of the International Atomic Energy Agency (IAEA); Rolf Heuer, Director General of CERN; Pascal Couchepin, former President of the Swiss Confederation; and Claude Haegi, President of the FEDRE, to name just a few. The ThEC13 proceedings are a source of reference on the use of thorium for energy generation. They offer detailed technical reviews of the status of thorium energy technologies, from basic R&D to industrial developments. They also describe how thorium can be used in critical reactors and in subcritical accelerator-driven systems (ADS), answering the important questions: – Why is thorium so attractive and what is the role of innovation, in particular in the nuclear energy domain? – What are the national and international R&D programs on thorium technologies and how are they progressing? ThEC13 was organized jointly by the international Thorium Energy Committee (iThEC), an association based in Geneva, and the International Thorium Energy Organisation (IThEO). It was held in the Globe of Science and Innovation at the European Organization for Nuclear Research (CERN), Geneva, Switzerland, in October 2013.